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Formation and lig
aBeijing National Laboratory for Molecu
Bioorganic Chemistry and Molecular Eng
University, Beijing 100871, China. E-mail: wbState Key Laboratory of Elemento-Organic
300071, ChinacSchool of Chemistry and Chemical Engin
Xiangtan, 411104, China
† Electronic supplementary information (1519012 and 1539530. For ESI and crystallformat see DOI: 10.1039/c7sc02018j
Cite this: Chem. Sci., 2017, 8, 6852
Received 4th May 2017Accepted 26th July 2017
DOI: 10.1039/c7sc02018j
rsc.li/chemical-science
6852 | Chem. Sci., 2017, 8, 6852–6856
and-based reductive chemistry ofbridged bis-alkylidene scandium(III) complexes†
Wangyang Ma, a Chao Yu, a Yue Chi, a Tianyang Chen, a Lianjun Wang, ac
Jianhao Yin, a Baosheng Wei, a Ling Xu, a Wen-Xiong Zhang *ab
and Zhenfeng Xi a
The chemistry of rare-earth carbene and alkylidene complexes including their synthesis, structure and
reaction is a challenging issue because of their high reactivity (or instability) and the lack of synthetic
methods. In this work, we report the first synthesis of the bridged bis-alkylidene complexes which
feature a 2-butene-1,1,4,4-tetraanion and four Sc–C(sp3) bonds by the reaction of 1,4-dilithio-1,3-
butadienes with ScCl3. This reaction proceeds via two key intermediates: an isolable
scandacyclopentadiene and a proposed scandacyclopropene. The scandacyclopentadiene undergoes
b,b0-C–C bond cleavage to generate the scandacyclopropene, which then dimerizes to afford the
bridged bis-alkylidene complex via a cooperative double metathesis reaction. Reaction chemistry study
of the bridged bis-alkylidene complex reveals their ligand-based reduction reactivity towards different
oxidants such as hexachloroethane, disulfide and cyclooctatetraene.
Transition metal carbene and alkylidene complexes have beenextensively studied because of their importance in organome-tallic chemistry, coordination chemistry and synthetic organicchemistry.1 In contrast, rare-earth metal carbene and alkylidenecomplexes are very limited mainly due to the energy mismatchbetween the rare-earth metals and ligand orbitals.2–12 Since therare-earth alkylidene complex was rst postulated in 1979,3
pioneering works have been made to isolate and characterize it.Some pincer-like rare-earth alkylidene complexes have beenreported independently by Cavell,4 Liddle,5 and Mezailles.6 Veryrecently, Cui et al. reported the lutetium methanediide-alkylcomplexes,7 and Chen et al. reported the non-pincer-typemononuclear scandium alkylidene complexes.8 Furthermore,rare-earth methylidene complexes were also stabilized by chlo-ride bridges9 or Lewis-acids such as AlMe3.10 Interestingly,mixed methyl/methylidene complexes11 and cubane-like meth-ylidene complexes12 have been reported. Despite these recentadvances, the chemistry of rare-earth alkylidene complexes isstill in its infancy, and the bridged bis-alkylidene complexremains scarce.
lar Sciences, MOE Key Laboratory of
ineering, College of Chemistry, Peking
Chemistry, Nankai University, Tianjin,
eering, Hunan Institute of Engineering,
ESI) available. CCDC 1555495, 1504242,ographic data in CIF or other electronic
Reductive reaction of rare-earth organometallic compoundsis a fundamental process in organometallic chemistry andcoordination chemistry.13 Rare earth metal complexes (Ce, Sm,Eu and Yb) supported by redox-inert ligands tend to performa single electron redox process. The utilization of redox-activeligands at the rare earth metal centers is an alternativestrategy for affording multi-electron redox reactivity.14 Ligand-based reductive chemistry of trivalent rare-earth organome-tallic compounds has received much attention. Evans andcoworkers have made great progress in studying the reductivereactivity of (C5Me5)3Ln (Ln ¼ La, Nd, Sm, etc.) and provideda wide variety of new reductive chemistry for rare earthmetals.13a,15
Herein, we report the rst synthesis of the bridged bis-alkylidene complex featuring a 2-butene-1,1,4,4-tetraanion andfour Sc–C(sp3) bonds from 1,4-dilithio-1,3-butadienes andScCl3. This reaction proceeds via two key intermediates: scan-dacyclopentadiene16,17 and scandacyclopropene.18,19 DFT calcu-lations indicate that the dimerization of scandacyclopropenesvia the cooperative double metathesis is the key factor for theformation of the bridged bis-alkylidene complex. Interestingly,the bridged bis-alkylidene scandium(III) complex shows unex-pected ligand-based two-electron or four-electron reductionreactivity towards different oxidants such as hexachloroethane,disulde and cyclooctatetraene.
Silyl-substituted 1,4-dilithio-1,3-butadienes 1a–cwere readilyprepared according to our previous procedure.20 When the 1 : 1reaction of 1a and solvated ScCl3 in THF was conducted at�20 �C, the light yellow crystalline complex 2a could be isolatedexclusively in 65% yield (Scheme 1). An X-ray analysis of 2a
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Scheme 1 Synthesis of scandacyclopentadiene 2a and bridged bis-alkylidene scandium(III) complexes 3a–c.
Fig. 1 Molecular structure of complex 2a with thermal ellipsoids at30% probability. H atoms are omitted for clarity.
Fig. 2 Molecular structure of complex 3a with thermal ellipsoids at30% probability. H atoms and two [Li(THF)4]
+ counterions are omitted
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revealed that it is a LiCl-ligated scandacyclopentadiene (Fig. 1).The Sc(III) center adopts a distorted octahedral fashion bondedwith two C(sp2) atoms, two chlorides and two THF molecules.The C1–C2 (1.348(4) A) and C3–C4 (1.376(4) A) bond lengths arewithin the range of standard C]C bond lengths, and the C2–C3bond length (1.520(3) A) indicates a typical C–C single bond.These data of bond lengths clearly show the butadienyl dia-nionic structure in 2a.
Complex 2a is sensitive to air and moisture but stable underdry N2 atmosphere. In the 1H NMR spectrum in THF-d8,a singlet at�0.38 ppm was observed and assigned to the protonresonance of TMS groups. Two b-C(sp2) atoms (C2 and C3)displayed a singlet at 167.6 ppm in the 13C NMR spectrum,while two a-C(sp2) atoms (C1 and C4) showed a broad peak at203.8 ppm, probably due to the coupling with scandium(nuclear spin quantum number I ¼ 7/2). The 1H NMR spectrumof 2a in THF-d8 showed no obvious change for 2 weeks at roomtemperature. However, when the THF-d8 solution of 2a washeated at 45 �C for 3 h or 80 �C for 10 min, the TMS protonresonance at�0.38 ppm completely disappeared in the 1H NMRspectrum, and two new singlets integrated to the same numberof protons appeared at �0.23 ppm and 0.20 ppm (see ESI† formore details). The singlet at 0.20 ppm was assigned to the TMSproton resonance of PhC^CTMS by comparison with its
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standard spectrum. The GC retention time and molecular ionpeak (m/z ¼ 174) detected by GC-MS are also consistent withthose of the standard sample of PhC^CTMS. The other newsinglet at �0.23 ppm was assigned to the TMS groups of a newcomplex 3a, which was obtained in almost quantitative yield bythermolysis of 2a. Furthermore, we found that the synthesis of3a does not require isolation of 2a as the starting material. 3acould be conveniently prepared by the reaction of 1a withsolvated ScCl3 in THF solution at 80 �C for 3 h. Similarly, 3b and3c could be prepared from the corresponding 1,4-dilithio-1,3-butadienes and ScCl3 (Scheme 1).
An X-ray analysis of 3a reveals it is a bridged bis-alkylidenecomplex and adopts a dimeric ate complex via m2-chloridebridges (Fig. 2). One scandium center (e.g. Sc1) is bonded withtwo carbon atoms and two terminal chlorides, while the otherone (e.g. Sc2) is bonded with two carbon atoms, two bridgedchlorides and one THF. The Sc1–Sc2 distance (3.1366(9) A) isthe shortest length found in the literature, which is notablyshorter than those in dinuclear scandium hydride complexes(3.20–3.40 A).21 Two lithium atoms act as counterions, and eachlithium atom forms a distorted tetrahedron surrounded by fourTHFmolecules. The bond lengths of C1–C2 (1.468(4) A) and C3–C4 (1.465(5) A) in 3a are signicantly longer than those in 2a[C1–C2, 1.348(4) A; C(3)–C(4), 1.376(4) A]. The bond length ofC2–C3 (1.430(4) A) in 3a is signicantly shorter than the corre-sponding C2–C3 (1.520(3) A) in 2a. Thus, the bond lengths inthe C1–C2–C3–C4 moiety in 3a are averaged and are not theclassical bond lengths of C–C single and double bonds. Theseresults show that 3a has a highly delocalized structure witha tetraanionic ligand. Most importantly, these results are instriking contrast with what was observed previously for thetransmetalation reactions of 1,4-dilithio-1,3-butadienes withmetal salts which gave 1,3-butadiene-1,4-dianion complexes.20
The formation of the asymmetric unit in 3a from twomolecules of 2a along with elimination of two alkynes is a veryinteresting process and intrigued us to explore the reactionmechanism. The crossover reaction between 2a and 2a-D10 wascarried out. When the reactionmixture was quenched with H2O,4a, 4a-D5, and 4a-D10 could all be detected by HRMS (Scheme 2).This result unambiguously reveals that the 2-butene-1,1,4,4-tetraanion moiety in 3a should be originated from two
for clarity.
Chem. Sci., 2017, 8, 6852–6856 | 6853
Scheme 2 The crossover-reaction between 2a and 2a-D10.
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molecules of scandacyclopentadienes instead of a simplereduction of a diene moiety in one scandacyclopentadiene.Thus, the crossover experiment excludes two possible pathwaysinvolving two eliminated alkynes from the same scandacyclo-pentadienes: (i) the cooperative intermolecular redox process,and (ii) stepwise intermolecular redox via the scandacyclopro-pene process (see ESI† for more details).
Based on the above information, we proposed a mechanisminvolving the scandacyclopropene intermediate. For a betterunderstanding of the formation of 3a, DFT calculations werecarried out using Gaussian 09 (Fig. 3).22 We chose the LiCl-freescandacyclopentadiene IM1 as a starting model compound andthe THF-ligated monomer 3a-M as a targeted compound forsimplicity.23 The structures of all of the minima and transitionstates were optimized at the B3LYP24/LANL2DZ (for Sc)/6-31+G*(for other elements) level in the gas phase. The effect of thesolvent was examined by performing single-point self-consistent reaction eld (SCRF) calculations based on thepolarizable continuum model (PCM) for gas-phase optimized
Fig. 3 DFT calculated energy profiles of related intermediates and tranlines: newly formed bonds).
6854 | Chem. Sci., 2017, 8, 6852–6856
structures. Scandacyclopentadiene IM1 will undergo b,b0-C–Cbond cleavage to generate scandacyclopropene IM2 by release ofone equiv. of alkyne. The b,b0-C–C bond cleavage from IM1 toIM2 is the critical step with the highest energy barrier of 13.3kcal mol�1 in the solution phase, which means that IM1 isisolable. Metallacyclopropenes, as an important class of reactiveintermediate, have been isolated and characterized in transi-tion and main group organometallic chemistry.18,19 The metal-lacyclopropene, e.g. aluminacyclopropene, can undergodimerization to give a 1,4-dialuminacyclohexadiene.25 Incontrast, rare-earth metallacyclopropenes are unknown. IM2 isthe rst optimized structure of a rare-earth metal-lacyclopropene by DFT calculations. Next, we tried to optimizethe dimeric structure of IM30 which is similar to 1,4-dia-luminacyclohexadiene. However, the optimization of thestructure of IM30 to a local energy minimum failed, probablybecause of its high energy and instability. Rather than givingIM30, a new intermediate, IM3, resulting from two IM2 speciesapproaching each other via the weak Sc–C interaction, wasoptimized to a local minimal energy, 2.7 kcal mol�1 lower thanIM2. Surprisingly, a cooperative double metathesis of IM3 gives3a-M via the transition state TS2. In TS2, two scandacyclopro-pene rings adopt a triangular prism geometry, in which each Scatom is coordinated to another carbon neighbouring TMSgroup. This geometry of TS2 could also explain the selectivity ofC(Ph)–C(Ph) coupling.
The structure of 3a features the 2-butene-1,1,4,4-tetraanionmoiety and thus we thought it could be oxidized to generatethe diene moiety in 2a, as illustrated in Scheme 3. As we ex-pected, 2a was generated by treatment with two equivalents ofhexachloroethane as an oxidant (Scheme 3a). This reactionresulted in the formation of ScCl3 which can be characterized asa ScCl3(THF)3 adduct by X-ray analysis, along with two equiva-lents of tetrachloroethylene which were identied using the 13CNMR spectrum and GC-MS. When four equivalents of
sition-states in the generation of 3a-M (red lines: broken bonds; blue
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Scheme 3 Ligand-based reduction reactivity of 3a towards differentoxidants.
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hexachloroethane were used and the reaction mixture washeated at 80 �C, 3a was transformed to PhC^CTMS and ScCl3(Scheme 3b). Furthermore, when disulde 5 served as anoxidant,26 the reaction of 3a with 5 provided complex 6 (see ESI†for the X-ray structure of 6, Scheme 3c) along with the formationof PhC^CTMS. When 3a was treated with cyclooctatetraene at80 �C, cyclooctatetraene was reduced to the cyclooctatetraenedianion. The corresponding complex 7 (see ESI† for the X-raystructure of 7, Scheme 3d) could be isolated aer beingrecrystallized in DME (DME ¼ 1,2-dimethoxyethane) in highyields along with the formation of PhC^CTMS. These resultsclearly show that the bridged bis-alkylidene scandium(III)complex 3a can act as an efficient two-electron or four-electronreductant.
Conclusions
In summary, we have developed a simple and efficient syntheticmethod for the rst series of well-dened bridged bis-alkylidenescandium(III) complexes from 1,4-dilithio-1,3-butadienes and
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ScCl3. This reaction proceeds via two key intermediates: anisolable scandacyclopentadiene and a proposed scandacyclo-propene. A mechanistic pathway of C–C bond recombinationthrough the dimerization of scandacyclopropene intermediatesis elucidated well by DFT calculations. Bridged bis-alkylidenescandium(III) complexes are found to show ligand-basedreduction reactivity towards different kinds of oxidant.Further reaction chemistry of bis-alkylidene scandium(III)complexes and characterization of scandacyclopropenes are inprogress.
Conflicts of interest
There are no conicts of interest to declare.
Acknowledgements
This work was supported by the Natural Science Foundation ofChina (no. 21572005, 21372014).
Notes and references
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18 Selected reviews on metallacyclopropenes: (a) K. D. J. Parkerand M. D. Fryzuk, Organometallics, 2015, 34, 2037–2047; (b)U. Rosenthal, V. V. Burlakov, P. Arndt, W. Baumann andA. Spannenberg, Organometallics, 2003, 22, 884–900.
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22 M. J. Frisch, et al., Gaussian 09 (Revision C.01), Gaussian,Inc., Wallingford CT, 2010, for full reference, see ESI.†
23 The Sc–O interaction is much stronger than the Sc–Clinteraction because of the oxophilicity of rare-earthelements. In THF, LiCl in 2a will be easily replaced by THFto yield a LiCl-free complex IM1. Based on the effects ofthe THF atmosphere, we excluded LiCl from thecalculation. In THF, 3a tends to be a monomer due to thesolvent coordination interaction. Furthermore, the bondlengths and angles of the calculated monomeric structureare similar to those of the crystal dimeric structure. Thus,we think the calculation of monomer 3a-M is enough todescribe the reaction pathway.
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